A Tubular Linear Magnetic Gear/Generator Set for Harvesting Slow-Motion Renewable Energy

Cheng Tsung Liu; Chang Chou Hwang; Kuo Yuan Hung

doi:10.4028/www.scientific.net/MSF.856.285

Paper Titles

Saturation Effects on the Parameters of Interior Permanent Magnet Synchronous Motors with Different Rotor Configuration
p.257

Interior PM Motor Torque Control and Performance Analysis Considering Saturation and Cross Magnetization Effects for Electric Traction
p.263

Particular SRM Design Methodology Based on Similarity Theory, Scale Factors and FEM
p.269

Study of Photovoltaic Systems’ Performances with Different Module Types
p.279

A Tubular Linear Magnetic Gear/Generator Set for Harvesting Slow-Motion Renewable Energy
p.285

Experimental Investigation of the Response of Different PLL Algorithms to Grid Disturbances
p.291

The Study of Heat Consumption Systems of Buildings with Heat Pump
p.297

An Algorithm to Detect Partial Shading Conditions in a PV System
p.303

Comparison of Thin Film Modules Productivity for Building Integration
p.309

HomeMaterials Science ForumMaterials Science Forum Vol. 856A Tubular Linear Magnetic Gear/Generator Set for...

A Tubular Linear Magnetic Gear/Generator Set for Harvesting Slow-Motion Renewable Energy

Abstract:

This paper will provide the design experience of a linear magnetic gear/generator set that can be incorporated with those slow-motion reciprocating renewable energy sources directly. The tubular system is equipped with one linear magnetic gears set and one linear permanent magnet generator integrated coaxially, and the external mechanical forces can be incorporated to the outer low-speed mover of the system. Through proper magnetic coupling designs, the conveyed electromagnetic energy can be coupled to the internal stator winding coils to produce the desired electric power output. By introducing the detailed three-dimensional finite element analyses and the Taguchi’s method for assisting the system design assessments, a laboratory prototype with 15 cm in diameter and 30 cm in length has been developed, and preliminary results showed that a power rating of 220 W can be achieved at a reciprocating frequency of 5 Hz along with an operational stroke of ±2.0 cm.